Introduction

Stromatolites are abundant throughout the Earth's geological records. The oldest examples of these preserved formations are more than 3 billion years old and are found mainly in Western Australia and South Africa (Lowe, 1980; Walter et al., 1980; Byerly et al., 1986). Recent studies have reflected a widespread and growing acceptance of the oldest stromatolites from the Pilbara region of Western Australia as biogenic (Allwood et al., 2006). However, the limited information preserved in fossil stromatolites has prompted studies on extant systems as crucial to understanding the process of their formation. Prominent examples of modern stromatolites can be found in the hypersaline region of Hamelin Pool, Western Australia (Hoffman, 1976; Playford and Cockbain, 1976), and in the open marine waters of Exuma Sound, Bahamas (Dravis, 1983; Reid et al., 2000). These modern analogues provide us with a template of how Earth and its early biosphere may have co-evolved.

Sediment trapping and binding and/or mineral precipitation by microorganisms led to the formation of the Bahaman stromatolites (Reid et al., 2000). In particular, filamentous cyanobacteria of the genus Schizothrix were shown to be responsible for the binding and trapping of sand grains, whereas coccoid cyanobacterial populations provided structural support for the growth of the stromatolites. In addition, both heterotrophic aerobic and anaerobic bacteria, which synthesize low-molecular weight organic compounds and amorphous exopolymers, were also present in these structures (Visscher et al., 1998). In contrast to the Bahaman stromatolites, the Shark Bay communities exhibit a greater diversity of archaea, cyanobacteria and heterotrophic bacteria (Burns et al., 2004; Papineau et al., 2005; Leuko et al., 2007). Shark Bay stromatolite communities are characterized by cyanobacteria belonging to the genera Synechococcus, Xenococcus, Microcoleus, Leptolyngbya, Plectonema, Symploca, Cyanothece, Pleurocapsa, Nostoc and Prochloron (Burns et al., 2004; Papineau et al., 2005). These initial studies identified more than 20 of the 52 known divisions of bacteria, as well as archaeal communities, including both Euryarchaeota and Crenarchaeota gene sequences. Comparison between stromatolites of differing morphology was also related to specific changes in the microbial community present. Recent studies on both Shark Bay and Bahaman stromatolites have revealed that eukaryotes are scarce in these formations (Reid et al., 2000; Burns et al., 2004; Papineau et al., 2005), though a variety of flagellates have been documented from Shark Bay (Al-Qassab et al., 2002). It has been proposed that stromatolites thrive in environments that exclude many higher organisms, particularly those that may graze on the resident microorganisms.

To date there have been no studies comparing the microbiology of morphologically similar stromatolites over temporal scales, or assessing the prokaryotic populations of the surrounding seawater. This latter feature is particularly important in attempting to assign populations specific to the geological morphogenesis and to further our understanding of the ecology and dynamics of modern stromatolite communities. Here, apart from these microbial diversity and functional assignments, scanning electron microscopy and fluorescence in situ hybridization were also performed on stromatolite sections to examine the spatial distribution and interaction of specific microorganism groups within these stromatolites.

Materials and methods

Sample description and sample sites

Hamelin Pool in Western Australia spans an area of ca. 1220 km2 with an average tidal range of ca. 60 cm (Logan and Cebulski, 1970). High net evaporation rates and average water temperatures throughout the year between 17 and 27 °C create a hypersaline environment with at least twice the salinity of seawater (Arp et al., 2001). Intertidal columnar stromatolites (Figure 1) were collected during the late afternoon in November 2002 from Telegraph Point (26°25′00″S, 11H°13′05″) on the south eastern shore of Hamelin Pool, Shark Bay, Western Australia, using methods described earlier (Burns et al., 2004). Samples were collected during low tide and a rock hammer was used to physically remove small sections with a vertical interval of 2 cm from the top of the stromatolite. Seawater surrounding the stromatolites was collected in sterile containers immediately before the collection of stromatolite samples.

Figure 1
figure 1

Images of stromatolites and the sample site at Hamelin Pool, Shark Bay. (a) Low tide at Telegraph Point showing stromatolites. (b) Sample HPS2. (c) A slide of sample HPS1 (Burns et al. (2004)) and (d) a slide of sample HPS2. Both (c) and (d) were embedded in epoxy resin and sectioned to a width of 30 μm; photograph taken using light microscopy (magnification= × 4).

Samples were placed in sterile specimen bags and stored in the dark at 4 °C during transportation. All samples were collected and handled with sterile instruments throughout the course of the study. The stromatolite sample analysed here was designated as HPS2 and another stromatolite surface section collected from the same location was designated as HPS1 (Burns et al. 2004). Although both samples were obtained from different stromatolites, they were obtained from morphologically identical columnar stromatolites in the intertidal region, both exhibiting a dark green and black pustular surface. These samples (HPS1 and HSP2) also have the same morphology as the stromatolite sample (HPIRR) analysed by Papineau et al. (2005). In contrast, sample HPDOM (Papineau et al., 2005) had a smooth domal surface. All samples were collected in the late afternoon. The interior of the sample analysed in this study consisted of fine grains as shown in the image of the cross-section from HPS2 (Figure 1d). The interior of HPS1 (Figure 1c) also showed that this sample consisted of similar fine grains. These both resembled the intertidal fine-grained stromatolites built by cyanobacteria as described in earlier studies by Awramik and Riding (1988). All samples were stored at 4 °C and DNA extraction and microorganism isolation were conducted immediately upon sample return.

Scanning electron microscopy

Fractured stromatolite samples were fixed in 3% glutaraldehyde solution, washed with 0.1 M sodium cacodylate buffer and stored at 4 °C. The samples were dehydrated in an ethanol series (50–100%), vacuum dried and sputter coated with gold using EmiTech K550 × gold sputter coater. Specimens were examined in a Leica Cambridge S360 scanning electron microscope set at an accelerating voltage of 20.0 kV with a lens-to-specimen working distance of 25 mm and a beam current of 100 pA.

Culturing and isolation

Isolation of bacteria, cyanobacteria and archaea from HPS2 and seawater was carried out by modifying BG-11 media (Rippka et al., 1981), Luria–Bertani media (Sambrook et al., 1989) and DSM97 (DasSarma et al., 1995), respectively. The salt concentrations of the different media were modified by the addition of NaCl (852 mM), KCl (18.6 mM), CaCl2 (18.4 mM), MgCl2 (90 mM) and MgSO4 (54 mM). This was conducted to mimic the hypersaline conditions of Hamelin Pool as described earlier (Burns et al., 2004), to isolate heterotrophic bacteria, cyanobacteria and halophilic archaea from this hypersaline environment. Owing to the higher concentration of sodium chloride in DSM97, no addition of this salt was made to this medium. To further facilitate the isolation of the slow-growing halophilic archaea from the faster growing bacteria, three antibiotics at 100 mg ml−1 (streptomycin, penicillin and ampicillin) were added to the modified DSM97 media (Wais, 1988).

DNA isolation and PCR amplification of 16S rRNA genes

Genomic DNA extraction of isolates was performed with an extraction protocol utilizing xanthogenate (Tillett and Neilan, 2000). The total genomic DNA from ground stromatolite was extracted using the TNE buffer extraction protocol (Neilan et al., 2002). Modifications to this protocol were carried out to improve cell lysis by extending the lysozyme step (>1 h) and the inclusion of four freeze–thaw cycles. Genomic material from two litres of seawater was concentrated by centrifugation and then extracted using the same extraction protocol as for the stromatolites. PCRs were performed using 1 U Taq polymerase (Fischer Biotech, Perth, Western Australia, Australia), 2.5 mM MgCl2, 10 × Taq polymerase buffer (Fischer Biotech), 0.2 mM dNTPs (Fischer Biotech) and 0.2 pM of each primer. Thermal cycling was performed in a GeneAmp PCR System 2400 Thermocyler (Perkin Elmer, Norwalk, CT, USA). Primer pairs used for the amplification of the bacterial, cyanobacterial and archaeal 16S rRNA genes were 27F1(5′-AGAGTTTGATCCTGGCTCAG-3′)/1494Rc (5′-TACGGTTACCTTGTTACGAC-3′)/809R (5′-GCTTCGGCACGGCTCGGGGTCGATA-3′) and 21F(5′-TTCCGGTTGATCCYGCCGGA-3′)/958R (5′-YCCGGCGTTGAMTCCAATT-3′), respectively. Thermal cycling conditions for the amplification of bacterial 16S rRNA genes were initial denaturation step at 92 °C for 2 min, followed by 30 cycles of denaturation at 92 °C for 10 s, primer annealing at 52 °C for 15 s, strand extension at 72 °C for 90 s and a final extension step at 72 °C for 7 min. Thermal cycling conditions for the amplification of cyanobacteria were as per standard protocols (Jungblut et al., 2005), and the amplification of archaeal 16S rRNA genes was carried out as described earlier (DeLong, 1992).

Construction of 16S rDNA clone libraries

Amplified archaeal-, universal bacterial- and cyanobacterial-specific 16S rRNA gene PCR products from total genomic DNA extracted from HPS2 and seawater were cloned into the p-Gem T Easy Vector System (Promega, Madison, WI, USA). Ligations and transformations were performed according to the manufacturer. For each sample and set of primers used, at least 100 positive (insert containing) clones were selected. Restriction fragment length polymorphism (RFLP) analysis was performed with PCR products using restriction enzymes AluI and ScrF1 (Fermentas, Hanover, MD, USA) (Jungblut et al., 2005). Clones were then grouped according to their different restriction patterns and a clone representing each pattern was sequenced. Automated sequencing was carried out using the PRISM Big Dye cycle sequencing system and ABI 3730 Capillary Applied Biosystem (Foster City, CA, USA) using Polymer 7.

Estimation of microbial diversity

Distance matrices were generated in ARB using the neighbour-joining method with the Jukes and Cantor correction. The program DOTUR (Schloss and Handelsman, 2005) was used to cluster sequences into operational taxonomic units by pair-wise identity (95–100% ID) with a furthest-neighbour algorithm and a precision of 0.01. Rarefaction curves, richness estimations (Chao1) and diversity indices (Shannon–Wiener) were calculated using DOTUR with default settings and 1000 random sample repetitions. Coverage (C) values were calculated by the method of Good with the equation C=[1−(n/N)] × 100, where n is the number of phylotypes in a sample represented by one clone (singletons) and N is the total number of clones examined (Good, 1953).

Phylogenetic sequence analysis

All sequences were analysed for chimaeras using methods described by Huber et al. (2004) and Cole et al. (2003). Chimaeras were not detected in the clones obtained. Sequence identities were determined by Basic Local Alignment Search Tools (BLAST) results and phylogenetic analysis. The 16S rRNA gene sequences were aligned and analysed using the ARB software package (Ludwig et al., 2004). The resulting alignments were manually checked and corrected when necessary. Phylogenetic trees were constructed using the maximum likelihood method (default parameters for ARB and fastDNAml) and the alignment of near full-length sequences (>1000 bp) of reference strains. Aligned partial 16S rRNA gene sequences (<1000 bp) were then inserted without changing the overall tree topology using the parsimony tool within ARB. This was necessary as sequences from a study on these stromatolite populations conducted by Papineau et al. (2005), samples designated as HPDOM and HPIRR, targeted different regions of the 16S rRNA genes as compared with this study and the study by Burns et al. (2004). Bootstrap values were obtained for branching patterns by using the PHYLIP software package (Retief, 2000), and values >50% were included for the main nodes of the tree. 16S rRNA gene sequences from earlier studies on the Shark Bay stromatolites (Burns et al., 2004; Papineau et al., 2005) were included for the determination of differences in the populations.

Fluorescence in situ hybridization of archaea and sulphate-reducing bacteria

Stromatolite samples (1 cm vertical section from the surface) for fluorescent in situ hybridization were fixed in 4% paraformaldehyde solution, washed with 1:1 phosphate-buffered saline–ethanol buffer and stored at 4 °C until required. Samples were then embedded in epoxy resin and sectioned to a width of 30 μm. Hybridization buffer containing an appropriate concentration of formamide and 50 ng of each probe (SRB385 5′-CGGCGTCGCTGCGTCAGG-3′ or Arch915 5′-GTGCTCCCCCGCCAATTCCT-3′) was applied to the slides, followed by incubation at 46 °C for 2 h. The samples were washed for 10–15 min in wash buffer pre-heated to 48 °C and subsequently rinsed with Milli-Q water. The slides were dried in the dark. Mountant and coverslip were applied, viewed and imaged using a confocal laser scanning microscope with argon–krypton laser.

Accession numbers

Sequences of the 16S rDNA clones and isolates are available under GenBank accession numbers EF150676EF150838.

Results and discussion

Microbial communities present in the stromatolites and the seawater surrounding these formations in Shark Bay were analysed with molecular phylogenetic methods. Isolation of cultivable microorganisms was also achieved by modifying the three culture media (Luria–Bertani, BG11 and DSM97 media) used in this study. The stromatolite sample (HPS2) analysed here had an irregular morphology and a dark green and black pustular surface. This is the same morphology as that described for both the samples studied previously, HPIRR (Papineau et al., 2005) and HPS1 (Burns et al., 2004). The sample interior of HSP2 consisted of fine grains as shown in the image of a cross-section (Figure 1d), similar to the cross-section of HPS1. Scanning electron micrographs indicated an association between carbonate and sand grains with filamentous bacteria (Figure 2), and boreholes, approximately 5–10 μm in diameter, were also evident. It is difficult at this stage to assign exact identities to these borers in the Shark Bay stromatolites; however, potential candidates include the range of unicellular coccoid cyanobacteria identified here (Table 1). These findings are consistent with the study carried out on Bahaman stromatolites (Reid et al., 2000), where boring activities of microorganisms (microboring) was characterized by boreholes surrounded by needle-like aragonite crystals. Lithified layers of micritized carbonate sand grains were also evident (Figure 2), and this is likely to be a result of continuous microboring.

Figure 2
figure 2

Scanning electron micrographs of Hamelin Pool stromatolite (HPS2). (a) Filamentous cyanobacteria binding carbonate sand grains. (b) Borehole, as shown by the arrow, is approximately 5–10 μm in diameter filled with needle-like microcrystalline structure, most probably aragonite (another form of calcium carbonate), and (c) welding of carbonate sand grains and in-filling of boreholes as a result of continued microboring.

Table 1 Summary of bacteria isolated from HPS2 and seawater surrounding Shark Bay stromatolites

Isolation of microorganisms from stromatolite sample HPS2 and surrounding seawater

A total of 25 archaeal isolates and 63 bacterial isolates (of which 42 isolates belonged to cyanobacterial genera) were cultivated. Their identities were determined based on GenBank BLAST analysis of their 16S rRNA genes. All 25 archaeal isolates showed a maximum of only 92% identity to Halobacterium NCIMB 718, an uncharacterized halophilic archaeon. One of these isolates was determined to be a new species belonging to the genus Halococcus (Goh et al., 2006). Bacteria belonging to the genera Bacillus, Salinivibrio, Halomonas, Marinobacter, Porphyrobacter, Idiomarina and two isolates with highest identity to the bacteria K2-13 and K3 were cultured from HPS2 (summarized in Table 1). Isolates with similarity to Alteromonas, Vibrio, Paracoccus and Roseibium were cultivated from the seawater. The cyanobacterial isolates had closest identity to Euhalothece, Gloeocapsa, Cyanothece, Oscillatoria, Geitlerinema, Xenococcus, Chroococcidiopsis, Gloeothece, Lyngbya and Dermocarpella (Table 1). No cyanobacteria were isolated from the surrounding seawater.

Clone library analysis of HPS2 and surrounding seawater

Amplification of 16S rDNA using universal bacterial, specific cyanobacterial and archaeal primers, and subsequent clone library construction was conducted on both total community DNA from the finely ground stromatolite samples and the surrounding seawater. Unique clones were identified by RFLP analysis. Clones of representative RFLP types were sequenced bi-directionally and compared with known sequences by BLAST analysis. From the archaeal clone libraries (93 clones), 10 RFLP groups were identified with BLAST results of sequences having closest identity to halophilic archaea. No archaeal 16S rRNA genes were amplified from the genomic DNA isolated from the seawater. Thirty-three unique RFLP groups were obtained from the stromatolite bacterial clone libraries (85 clones), whereas 19 groups were obtained from the seawater libraries (94 clones). In HPS2, the highest proportion of sequences were related to α-proteobacteria (29%) and γ-proteobacteria (29%), whereas the majority of clones in the seawater had sequence identities related to α-proteobacteria (69%) (Figure 3). A total of 96 clones were obtained for the stromatolite cyanobacterial library, with another 82 clones obtained from the seawater. Five groups were identified from the RFLP analysis of the stromatolite cyanobacterial library whereas eight groups were obtained from the seawater. The relative abundance of cyanobacterial clones is shown in Figure 3. The most abundant clones from HPS2 were affiliated with Gloeothece (52%) and Gloeocapsa (42%). The most abundant clones (56%) from the seawater cyanobacterial library were related to Euhalothece.

Figure 3
figure 3

Comparison of the most abundant sequences in the 16S rDNA clone libraries constructed for total bacteria and cyanobacteria from the sample HPS2 and seawater. (a) Total bacteria in sample HSP2. (b) Total bacteria in surrounding seawater. (c) Cyanobacteria in sample HSP2. (d) Cyanobacteria in surrounding seawater.

Estimated coverage and richness

The coverage and richness of the clone libraries were assessed by the method of Good (1953) for the calculation of coverage, the non-parametric estimator Chao1 for richness (Chao, 1984) and the Shannon–Wiener index for diversity (Table 2). Sequences were collected into operational taxonomic units by pair-wise identity (% ID) with a furthest-neighbour algorithm and a precision of 0.01. The estimated coverage for all the libraries constructed was 50% (Table 2), and collector curves for coverage for all libraries approached asymptotic (data not shown). This indicated that the coverage of the populations was comprehensive for these samples, and the libraries were representative samples of the microbial diversity. The cutoff for differentiation of species was chosen as 97% sequence identity; however, this probably underestimated the total bacterial diversity. The Chao1 richness estimate for HPS2 was highest for the bacterial population. The number of observed species from the total bacterial library was 33 with a Chao1 estimate of 44.67 (36.45–73.40), indicating that when sampled to completion, there would be between 4 and 40 more species obtained. Only 10 taxa were obtained from the archaeal library and when sampled to completion 3–20 more species would be obtained. The cyanobacterial library was sampled to completion. The number of operational taxonomic units, Chao1 richness estimates and the Shannon–Wiener diversity estimates also indicated that total bacterial diversity from HPS2 was greater than the surrounding seawater, whereas the opposite was observed for the estimates of cyanobacterial diversity.

Table 2 Coverage, observed phylotype richness, richness and diversity indices for clone libraries constructed from HPS2 and seawater

Comparison with known Shark Bay stromatolite microbial communities

Phylogenetic analysis of HPS2 and its surrounding seawater sequences was performed in ARB with the Greengenes database of full-length non-chimaeric 16S rRNA gene sequences (DeSantis et al., 2006). Partial sequences from earlier studies on samples HPS1, HPDOM and HPIRR (Burns et al., 2004; Papineau et al., 2005) were included for comparison to obtain a comprehensive understanding of the microbial diversity in this environment. The phylogenetic trees in Figures 4, 5 and 6 show the relative topologies of the sequences for the archaeal domain, the bacterial domain and for the cyanobacteria, respectively. As shown in Figure 4, all archael clones from HPS2, HPS1, HPDOM and HPIRR were related to Halobacteria from the Euryarchaeota. In particular, the Halococcus genus was represented by both clones and isolates from HPS2 and HPS1, an indication of their intrinsic persistence in this environment. In contrast to the archaeal population of HPS1, HPDOM and HPIRR, HPS2 contained no representatives of the Crenarchaeota. The results presented here indicate that there has been a decrease in the observed taxonomic units in archaeal diversity in these stromatolites possessing similar morphologies and from the same location. The halophilic archaeal sequences obtained from different samples over time generally had close phylogenetic affinities. However, no archaea were identified in the seawater surrounding the stromatolites using either culturing techniques or total DNA analyses. Although it is possible that archaea are present in concentrations in the seawater that are below the limits of detection of the methods employed here, it would seem that these halophilic organisms are specific to these biosedimentary structures (Goh et al., 2006). The role of archaea in stromatolites is not well understood, and thus it is difficult to assess their contributions. Could archaea also contribute to stromatolite formation? Although we can only speculate at this stage, it has been shown that some Haloarchaeal species are also capable of fixing carbon dioxide (Javor, 1988). Furthermore, the association of sulphate-reducing bacteria with archaea can result in the coupling of methane oxidation with sulphate reduction and can also lead to carbonate precipitation (Michaelis et al., 2002).

Figure 4
figure 4

Phylogenetic relationships of archaea from Shark Bay intertidal stromatolites. Sequences from stromatolites HPS2, HPS1 (Burns et al., 2004), HPDOM and HPIRR (Papineau et al., 2005) were highlighted in yellow, red, orange and pink, respectively. A coloured box beside a filled triangle indicates that a group of sequences were clustered together. Only bootstrap values >50% were considered significant. The scale bar represents 0.1 nucleotide changes per nucleotide position. SSU 16S rDNA sequences are available under GenBank accession numbers EF150811EF150838. The color reproduction of this figure is available on the html full text version of the manuscript.

Figure 5
figure 5

Phylogenetic relationships of total bacteria from Shark Bay intertidal stromatolites. Sequences from stromatolites HPS2, HPS1 (Burns et al., 2004), HPDOM and HPIRR (Papineau et al., 2005) and seawater were highlighted in yellow, red, orange, pink and blue, respectively. A coloured box beside a filled triangle indicates that sequences from more than one study were present. Only bootstrap values >50% were considered significant. The scale bar represents 0.1 nucleotide changes per nucleotide position. SSU 16S rDNA sequences are available under GenBank accession numbers EF150676EF150762. The color reproduction of this figure is available on the html full text version of the manuscript.

Figure 6
figure 6

Phylogenetic relationships of cyanobacteria from Shark Bay intertidal stromatolites. Sequences from stromatolites HPS2, HPS1 (Burns et al., 2004), HPDOM and HPIRR (Papineau et al., 2005) and seawater were highlighted in yellow, red, orange, pink and blue, respectively. A coloured box beside a filled triangle indicates that sequences from more than one study were present. Only bootstrap values >50% were considered significant. Scale bar represents 0.1 nucleotide changes per nucleotide position. SSU 16S rDNA sequences are available under GenBank accession numbers EF150763EF150810. The color reproduction of this figure is available on the html full text version of the manuscript.

Bacterial 16S rDNA sequence analysis revealed 16 groups belonging to α-proteobacteria, γ-proteobacteria, δ-proteobacteria, acidobacteria, Bacteriodetes/chlorobi, two unknown clades, candidate division OP-11, firmicutes, candidate division TM6, planctomycetes, actinobacteria, chloroflexi, cyanobacteria, Deinococcus and thermotogales (Figure 5). Groups containing sequences from the seawater comprised the α- and γ-proteobacteria, Bacteriodetes/chlorobi, planctomycetes, chloroflexi and cyanobacteria. The cyanobacterial cluster contained clones from both HPS2 and seawater (Figure 5). These clones from HPS2 showed highest sequence identity to Cyanothece, Gloeocapsa and Phormidium, whereas clones from the surrounding seawater had highest sequence identity to Euhalothece. However, using cyanobacterial-specific PCR primers, a greater diversity of cyanobacteria was observed (Figure 6). Analyses of the total bacterial community in this study indicated that the identities of cultivated organisms also differed from those of the 16S rDNA clone libraries. In particular, culturable Bacillus sp. appeared to dominate the Shark Bay stromatolites. One of the adaptive physiological responses to environmental stresses by Bacillus is spore formation (Nicholson, 2002), and the difficulty in extracting DNA from spores is a possible explanation for the lack of Bacillus 16S rRNA genes detected in the total genomic DNA from stromatolites in this and earlier studies. The majority of the stromatolite microbial communities were members of the proteobacteria/purple bacteria, firmicutes/Gram-positive bacteria, cyanobacteria and green sulphur bacteria, consistent with other reports on stromatolite-associated biodiversity (Bauld et al., 1979; Visscher et al., 1999; Reid et al., 2000). Bacteria belonging to the groups planctomycetes, proteobacteria/purple bacteria, cyanobacteria and the green sulphur bacteria were also identified in the surrounding seawater. These groups may therefore not be unique to these benthic geological communities; however, the dispersal of microorganisms from biofilms is a common phenomenon in the environment (Characklis, 1990; Brading et al., 1995).

The Shark Bay stromatolite cyanobacterial 16S rDNA sequences were affiliated to the orders Pleurocapsales, Chroococcales and Oscillatoriales. The Prochloron group was identified only from HPS1, whereas the surrounding seawater sequences were related to Chroococcales and Oscillatoriales. Three Pleurocapsales clades were identified to be Chroococcidiopsis (sequences from HPS1 and HPS2), Dermocarpella (sequences from HPS2) and Pleurocapsa (sequences from HPS2). Under the order Chroococcales, sequences from HPS1, HPS2 and the surrounding seawater were related to Gloeocapsa and Euhalothece spp. The Gloeothece group contained sequences from HPS2, HPIRR and HPDOM, whereas the Cyanothece group contained sequences from HPS1 and HPS2. Within the Oscillatoriales, most sequences from HPS1 belonged to Symploca, Plectonema and a novel clade of filamentous cyanobacteria. Sequences from HPS2 clustered with Leptolyngbya and Geitlerinema, whereas the HPIRR and HPDOM sequences clustered with Microcoleus sp.

The identification of sequences related to Schizothrix sp. from HPS2 agrees with reports carried out on the microbial composition of the Bahaman stromatolites (Reid et al., 2000), and these and other filamentous cyanobacteria identified here may play roles in stromatolite formation in Shark Bay through the binding and trapping of sediments (Reid et al., 2000). This corroborates the recent detection of unicellular coccoid cyanobacteria in modern stromatolites (Macintyre et al., 2000). Although the specific coccoid cyanobacterium found to be involved in the boring and in-filling of Bahaman stromatolites (Solentia sp.) was not identified here, unicellular coccoid cyanobacterial isolates with 16S rDNA sequences similar to Chroococcidiopsis sp., Xenococcus sp. and Dermocarpella sp. from the same order (Pleurocapsales) were present in all the three Shark Bay samples. In particular, HPS2 indicated the presence of a higher diversity of unicellular cyanobacteria compared with HPS1, whereas the overall diversity in HPS2 was lower compared with the other studies. In addition to the involvement of filamentous cyanobacteria in the formation of stromatolites, the identification of these unicellular cyanobacteria sp. (Euhalothece sp., Gloeothece sp., Gloeocapsa sp. and Chroococcidiopsis sp.) mirrors the composition of other hypersaline ecosystems (Garcia-Pichel et al., 1998; Nubel et al., 2000).

Microscopy

In earlier studies of the Bahaman stromatolites, cyanobacteria and sulphate-reducing bacteria were shown to be involved in their formation (Visscher, 2000). In both the present and earlier studies on microbial diversity in the Shark Bay stromatolites, microbial groups were detected based on phylogenetic affinities. To determine the spatial distribution of these microorganisms, thin sections from the top 1 cm of stromatolite samples were analysed by confocal microscopy. In addition, archaeal probes were employed to investigate the distribution of halophilic archaea in Shark Bay stromatolites. Cyanobacteria were detected by the autofluorescence of phycocyanin whereas archaea and sulphate-reducing bacteria were detected using labelled specific DNA probes. Cyanobacteria were located throughout the stromatolite section and, in particular, at the surface (Figure 7a). Archaeal cells were not located on the surface of the stromatolites, but were closely associated with the cyanobacterial cells below the surface (Figure 7b). Sulphate-reducing bacteria were localized to the surface and intermediate layers of the stromatolite section, and were also in close association with cyanobacteria. Although the cyanobacteria formed a distinct layer on the surface, there were no other apparent discrete layers of microorganisms observed within the stromatolite sections (Figure 7). The archaea and sulphate-reducing bacteria were instead irregularly localized with the cyanobacterial cells (Figure 7c).

Figure 7
figure 7

Krypton–Argon confocal images of FISH of cross-sections of Shark Bay stromatolite samples. (a) Image of a stromatolite cross-sectioned vertical surface dominated by unicellular cyanobacteria that constitute the black surface layer (Figures 1a and c). The autofluorescence of cyanobacteria is denoted in red whereas DNA in the sample was stained by SyBr Green and is denoted in green. Scale=10 μm. (b) FISH image of the interaction of cyanobacteria with archaea in the middle region of the stromatolite section with an FITC archaeal probe (green) and autofluorescence of cyanobacteria (red) is denoted in red. Scale=5 μm. (c) FISH image of the middle region of the stromatolite section showing sulphate-reducing bacteria (stained with FITC-SRB probe green) with cyanobacteria (denoted in yellow due to the overlap between autofluorescence of cyanobacterial pigments, phycocyanin red and phycoerythrin green). Scale=5 μm. Both (b) and c) were taken approximately 100 μm below the surface. FISH, fluorescence in situ hybridization; FITC, fluorescein isothiocyanate.

Conclusion

The microbial communities of modern stromatolites and surrounding seawater have been characterized and compared with the microorganisms identified earlier in this ecosystem. The presence of diverse metabolic groups of microorganisms indicated that this environment has a rich pool of genetic diversity and strongly suggests a high level of biological complexity in this ecosystem. The relative abundance of these microbial communities may influence the variety of geomorphologies observed; however, biases inherent in the present microbial and molecular analyses affords only limited quantitative interpretation of the data. The use of controlled and broadly accepted procedures ensures that the results can be readily related to similar investigations.

In terms of the microorganisms identified in both the stromatolites and the surrounding seawater, earlier studies have shown that the dispersal of biofilm members in surface water is common and is particularly relevant in this environment given that these microbial communities are subjected to abrasion, sloughing and erosion due to physical forces or nutrient depletion. Differences in microbial diversity of Shark Bay stromatolites apparent from the studies conducted to date may be in part due to these various environmental challenges leading to microbial succession, as shown to occur in the Bahaman stromatolites (Reid et al., 2000). The concept of succession is common in planktonic cyanobacterial and other autotrophic communities (Stevenson, 1983), as it is in biofilm populations (Santegoeds et al., 1998; Jackson et al., 2001). If the measured fluxes in these stromatolite populations are real, certain metabolisms critical for the geological formation would also respond to the prevailing conditions. One such factor is hypersalinity of the environment. Salinity gradients are formed due to tidal flows and the evaporation of seawater in the intertidal regions of Hamelin Pool. These gradients result in the presence of microbial species adapted to different ranges of salinity and could result in a reduction in the diversity of bacterial and archaeal communities at higher salinities (Benlloch et al., 2002; Jungblut et al., 2005). High levels and fluctuations in salinity also result in an increase in biodiversity and favour the growth of halophilic microorganisms (Wieland and Kuhl, 2006; Abed et al., 2007). It is evident from this study, and regardless of time and the type of stromatolite, that certain phenotypic groups, such as both unicellular and filamentous cyanobacteria and halophilic archaea, are consistent components of these environments and therefore likely to be intrinsic to the development of the stromatolites at Shark Bay. The information presented here is a platform to examine other functional characteristics of these systems, including salt tolerance, cell signalling and secondary metabolism (Burns et al., 2005). This study has also confirmed the importance of microbial community analyses of the Hamelin Pool stromatolites to understand the relationship between microbial populations, the conservation and ecophysiology of this particular environment, and how this may correlate with the morphology of extant and extinct stromatolites.